Whisker oven and method

ABSTRACT

AN OVEN FOR MAKING WHISKERS FROM A VAPOR COMPRISING A HOUSING CONTAINING A CHILLED BASE PLATE, A FIRST AND SECOND SUPPORT POST EXTENDING UPWARDLY FROM THE BASE PLATE, AN UPPER AND LOWER SUPPORT PALE MOUNTED ON THE POSTS, A HOLLOW HEATING ELEMENT MOUNTED BETWEEN THE SUPPORT PLATES, AND A STAGE WITHIN THE HEATING ELEMENT FOR SUPPORTING A SUBSTRATE ON WHICH WHISKERS ARE GROWN. THE SUBSTRATE IS COVERED WITH RHODIUM, AND MAY BE MADE OF A MATERIAL SELECTED FROM THE GROUP CONSISTING OF STAINLESS STEEL, BERYLLIUM OXIDE, ALUMINA, COPPER, COBALT, AND NICKEL THE METHOD INCLUDES PLACING A SUBSTRATE IN A WHISKER DEPOSTION ZONE OF WHISKER VAPOR AND DEPOSITING AND GROWING WHISKERS ON THE SUBSTRATE. THE METHOD ALSO INCLUDES COOLING THE BOTTOM OF THE WHISKER DEPOSITION ZONE TO FORM CONVECTION CURRENTS OF VAPOR, AND DEPOSITING AND GROWZONE, AND FEEDING THE VAPOR DOWNWARDLY INTO THE WHISKER DEPOSITION ZONE TO CLASH WITH THE UPWARDLY FLOWING VAPOR CONVECTION CURRENTS AND FORM A TURBULENCE IN THE WHISKER DEPOSITION ZONE. A ROTABLE DRUM POSIRIONED BELOW A NUCLEATING ZONE IN THE OVEN AND HAVING A POCKER THAT RECEIVES THE SUBSTRATE. A RACK GEAR OPERATED BY A MOTOR WITH A CLUTCH MOVES THE SUBSTRATE FROM THE NUCLEATING ZONE TO THE DRUM POCKET, AND A MOTOR GEAR SYSTEM ROTATES THE DRUM TO WIND THE WHISKERS IN THE FORM OF A ROVING ONTO THE DRUM SO THAT COURSES OF A SUCCEEDING LAYER OF ROVING LIE BETWEEN COURSES OF THE NEXT PROCEEDING LAYER HAVING COURSES RUNNING IN THE SAME DIRECTION.

May 28 1974 v E. F. HOLLANDER, JR I 3,313,224

WHISKER OVEN AND METHOD 4 Sheets-Sheet 1 Original Filed July 17, 1969 FIG. I.

May 28, 1974 WHISKER OVEN AND METHOD Original Filed July 17, 1969 4 Sheets-Sheet 2 6 RHODIUM, w 'i 300 SERIES FEED STAINLESS STEEL BERYLIUM OXIDE, ALUMINA, COPPER,COBALT;

OR NICKEL FIG. 2.

E. F. HOLLANDER, JR 3,813,224 v May 28, 1974 E. F. HOLLANDER, JR 2 WHISKER OVEN AND METHOD Original Filed July 17, 1969 4 Sheets-Sheet r 7 5 ISI May 28, 1974 E. F. HOLLANDER, JR 3,813,224

WHISKER OVEN ANDMETHOD- Original Filed July 17, 1969 4 Sheets-Sheet 4 United States Patent 3,813,224 WHISKER OVEN AND METHOD Edward F. Hollander, Jr., Broomall, Pa., assignor to John P. Glass, trading as Cava Industries, Essington, Pa. Original application July 17, 1969, Ser. No. 842,560, now

Patent No. 3,664,813. Divided and this application Dec.

27,1971, Ser. No. 212,353

Int. Cl. B01j 17/28 US. Cl. 23-273 SP 13 Claims ABSTRACT OF THE DISCLOSURE An oven for making whiskers from a vapor comprising a housing containing a chilled base plate, a first and second support post extending upwardly from the base plate, an upper and lower support plate mounted on the posts, a hollow heating element mounted between the support plates, and a stage within the heating element for supporting a substrate on which whiskers are grown. The substrate is covered with rhodium, and may be made of a material selected from the group consisting of stainless steel, beryllium oxide, alumina, copper, cobalt, and nickel. The method includes placing a substrate in a whisker deposition zone of whisker vapor, and depositing and growing whiskers on the substrate. The method also includes cooling the bottom of the whisker deposition zone to form convection currents of vapor passing upwardly through the zone, and feeding the vapor downwardly into the whisker deposition zone to clash with the upwardly flowing vapor convection currents and form a turbulence in the whisker deposition zone. A rotatable drum positioned below a nucleating zone in the oven and having a pocket that receives the substrate. A rack gear operated by a motor with a clutch moves the substrate from the nucleating zone to the drum pocket, and a motor gear system rotates the drum to wind the whiskers in the form of a roving onto the drum so that courses of a succeeding layer of roving lie between courses of the next preceding layer having courses running in the same direction.

CROSS-REFERENCE TO RELATED APPLICATIONS This application is a division of my patent application Ser. No. 842,560, filed July 17, 1969, now U.S. Pat. No. 3,664,813.

BACKGROUND OF THE INVENTION This invention relates to a method and an oven for making fibers or whiskers by condensing material from a vapor phase, and a drum for winding the whiskers into a coil in the form of a roving.

It has long been known that crystal structures are very much stronger than the same material in non-crystalline form. Accordingly, it has been desired to produce crystalline material having long, needle-like linear crystals, commonly referred to in the art as crystalline fibers or whiskers. Much Work is being done to develop a reilable method and apparatus for producing whiskers, such as graphite whiskers.

SUMMARY OF THE INVENTION It is an object of this invention to provide a method and apparatus for producing whiskers reliably and consistently, and for winding the whiskers into a coil. This involves providing an oven including a chilled base plate and a hollow heating element mounted above the base plate and stage positioned within the heating element for supporting a substrate on which the whiskers are grown.

The substrating may be made of a number of materials, and it has been found that when the substrate is covered with rhodium that whiskers are produced at a greatly 3,813,224 Patented May 28, 1974 BRIEF DESCRIPTION OF THE DRAWINGS Other objects and advantages of this invention, including its simplicity and economy, as well as the ease with which it may be adapted to existing equipment, will further become apparent hereinafter and in the drawings, in which:

FIG. 1 is a view, partly schematic, of whisker oven apparatus constructed in accordance with this invention;

FIG. 2 is a view in vertical section of the oven of FIG. 1;

FIG. 3 is a perspective and exploded view of an outer heat shield housing forming part of the oven;

FIG. 4 is a view partly in section of the winding apparatus of the invention;

FIG. 5 is a view in section taken as indicated by the lines and arrows 55 which appear in FIG. 4;

FIG. 6 is a view in section taken as indicated by the lines and arrows 66 which appear in FIG. 4; and

FIG. 7 is an exploded view in schematic form of feed structure located between nucleation zone and the drum of the winding apparatus.

Although specific terms are used in the following description for clarity, these terms are intended to refer only to the structure shown in the drawings, and are not intended to define or limit the scope of the invention.

DESCRIPTION OF THE PREFERRED EMBODIMENT Turning now to the specific embodiment of the invention selected for illustration in the drawings, there is shown a whisker oven 11 comprising a housing 13, an outer heat-shield 14, an inner heat-shield 15 containing a chilled base plate 16, a first support post 17 and a second support post 19 extending upwardly from base plate 16, an upper annular support plate 21 and a lower annular support plate 23 mounted on posts 17 and 19, a hollow graphite heating element 25 mounted between support plates 21 and 23, and a chilled stage 27 mounted within heating element 25 for supporting a substrate 29 on which whiskers 31 are grown.

Oven 11 includes electrical insulators 33 positioned between the posts 17, 19 and base plate 16. An electrical insulator 35 is positioned between support post 19 and upper support plate 21, and electrical insulator 37 is positioned between support post 17 and lower support plate 23. A source of electric current 39 is connected by electrical conductors 41 to support posts 17, 19 so that current flows through post 19, lower support plate 23, heating element 25, upper support plate 21, and downwardly through support post 17 to return to current source 39 to thereby heat the heating element 25.

Three molybdenum discs 43-45 are supported from posts 17, 19 by rods 47 and ring 48 and are positioned below heating element 25 to prevent excessive heat loss downwardly.

Above heating element 25, a molybdenum disc 49 is supported from posts 17, 19 by annular plate 51 and forms a heat shield for preventing excessive heat loss upwardly. Electrical insulators 53 are positioned between plate 51 and posts 17, 19 to prevent electrical current flow from posts 17, 19 to plate 51.

A hollow cylinder 55 of fused quartz is supported between plates 21 and 23 and is positioned around heating element 25 for preventing excessive heat loss outwardly.

A gas or vapor, such as methane or natural gas, is fed into oven 11 from a vapor source through a tube 59 encased in a stainless steel sleeve 61 threaded into base plate 16 and having a plastic insert 63 positioned between tube 59 and sleeve 61 to electrically insulate the tube 59 from base plate 16. Insert 63 is preferably made of Teflon, and a tube clamp 65 is provided for adjusting the vertical position of tube 59, since normally clamp 65 abuts the top of insert 63.

Apparatus is provided for varying the pressure in oven 11, and this apparatus includes a tank 67 (FIG. 1) connected to oven 11 by conduit 69, flowmeter 70, valve 71, and tube 59. Argon and methane, or hydrogen and methane are mixed together in mixing vessel or tank 67 which is similar in construction to oven 11, and the mixture of gases is fed into the interior of oven 11 until the desired pressure is reached. Satisfactory results in growing whiskers have been obtained at one atmosphere, but operation at about 4 or atmospheres is preferred. In any event, the pressure within oven 11 must be positive, since no deposition of whiskers has been obtained at negative pressures.

Vacuum line 74, sufficient to exhaust the furnace to torr, is provided for scavenging undesired vapors and gases, such as oxygen, from the furnace before beginning nucleation and growth of the crystal whiskers. Exhaust line 76 is provided for controlling the pressure in the furnace and for exhausting the unwanted decomposition products of the reaction, such as hydrogen in the case of methane.

While whisker deposition has been obtained using substrates made of a variety of materials, it has been found that when the substrate is made of some other materials there is no whisker deposition. For example, whisker deposition has been obtained when the substrate has been made of 300 series stainless steel without selenium or sulfur or similar agents used for free machining, beryllium oxide, alumina, copper, cobalt and nickel. Moreover, greatly accelerated graphite whisker deposition was obtained when the substrate was coated with rhodium. The rhodium appears to act as a catalyst and produces a fibrous, woolly, cotton-ball material which may be used to reinforce rubber, for example. The use of rhodium increased the nucleation and growth of the whiskers about ten thousand times.

Not all materials may be used as a substrate. For example, tests have shown that the following materials do not work as a substrate to produce graphite whisker deposition and growth: silica, aluminum, tungsten, molybdenum, gold, and silver.

The temperature of heating element may be varied by varying the output of the electrical current source 49. For graphite whisker nucleation and growth to occur at all, a specific thermal gradient is important and also the absolute temperature of the substrate is important. Moreover, the temperature must stay fixed and not wander. For example, the substrate temperature may be 1150 F. or 1250 F. but whichever temperature is chosen, the substrate should stay within about 1 F. of that chosen temperature.

Gas tube 59 extends upwardly and then curves downwardly to feed the gas downwardly into a whisker nucleating or deposition zone 72 around substrate 29 and form a turbulence with vapor convection currents created by the coolness of chilled base plate 16.

Base plate is cooled by a cooling tube 73 and outer heat shield 14 is cooled by cooling tubes 75.

Heating element 25 is supported on plate 23 by split ring clamps 77 and bolts 79, and stage 27 is supported by rods 81 that extend upwardly from disc 43.

An annular molybdenum disc 83 is positioned within heating element 25 above stage 27 and is supported by rods 85 that extend downwardly from molybdenum disc 49.

Fused quartz cylinder55 is held reasonably concentric to heating element 25 by a shoulder 87 on clamping ring 77.

Inner heat-shield 15 is preferably made of molybdenum, and is provided with an annular cover 89 having a hole 91 through which tube 59 projects downwardly toward nucleating zone 72.

Electrical conductors 95, 96 pass through the bottom of housing 13 and lead, respectively, to thermocouple 97 bolted to the bottom of stage 27 and to thermocouple 99 positioned between heating element 25 and quartz cylinder 55.

Whisker oven housing 13 is a split tank and is provided with vacuum and pressure gauges, side windows 101 for looking into the interior, and a larger window 103 at the top.

Outer heat-shield 14 is provided with a top wall 105 having three sight holes 106-108 of various sizes and a bearing 109 on which a top plate 111 is rotatable. Plate 111 has a sight hole 113 that may be positioned over any of sight holes 106-108 as desired so as to watch the nucleation in zone 72.

Substrate 29 is cylindrical in shape and the whiskers 31 grow on the outer surface of the cylinder. However substrates of different shapes may be used.

In practice, it has been noted that if there are too many vapor atoms in the oven trying to deposit on the substrate 29, proper nucleation does not occur. On the other hand, I have achieved nucleation, following careful purging of the oven by pumping the vacuum chamber to about ,5 micron, refilling the chamber with a clean inert gas such as argon and repeating these steps three times until the level of contamination is low, by setting the proper thermal gradient in the oven by heating the element 25 to about 1450" F. with the pressure in the oven 11 being a negative pressure, i.e. a vacuum. Then I flooded the oven 11 with natural gas containing methane until the pressure rose above fifteen millimeters of mercury to start deposition of whiskers. Then I dropped the temperature of the heating element 25 to about 1200 -F. and the growth of whiskers continued.

Chilled base plate 16 serves a dual purpose in that it protects the instruments below plate 16 from heat, and also promotes convection of vapor current in the oven to thereby stimulate and promote the growth of whiskers.

A temperature gradient exists between heating element 25 and substrate 29. Similarly, a temperature gradient exists between heating element 25 and the whisker growth ends 31. Satisfactory growth has been achieved when these gradients were between 300 F. per inch and 1200" F. per inch. This is a function of the geometry of the furnace.

The method of the present invention comprises placing a substrate 29 in a whisker deposition zone 72 of whisker vapor by placing substrate 29 on stage 27, and depositing and growing whiskers on the substrate 27. The substrate is made of a material selected from the group consisting of rhodium, stainless steel, beryllium oxide, alumina, copper, cobalt and nickel, and excellent results have been obtained from a beryllium oxide substrate coated with rhodium. Graphite whiskers have been grown using methane as the vapor, and also when using natural gas containing a high percentage of methane.

The temperature of the whisker vapor has been maintained in the deposition zone at about 1200 F., and whisker deposition has been obtained with the pressure at fifteen millimeters of mercury, one atmosphere, and up. However, no whiskers were obtained when the pressure in the oven has been negative.

The method also includes the steps of cooling the bottom of the whisker deposition zone by chilling plate 16 to form convection currents of vapor that pass upwardly through the vapor deposition zone, and feeding the vapor downwardly from tube 59 into the whisker deposition zone to clash with the upwardly flowing vapor convection currents and form a turbulence in the vapor deposition zone around the substrate 29.

Referring now more particularly to FIGS. 3-7, there is shown winding apparatus which may be incorporated in the whisker oven and positioned below a nucleating zone 72a that corresponds to nucleating zone 72 in FIG. 2. A base plate 16a corresponds to base plate 16 in FIG. 2. Most of the apparatus in FIG. 2 is duplicated in FIG. 5 but has been omitted for clarity. However, some of the structure of FIG. 2, the supporting structure lying between the nucleating zone 72 and base plate 16, is left out entirely because substrate 29a is adapted for movement downwardly from nucleating zone 72a through a hole 115 in plate 161: to seat in a pocket 117 formed in a drum 119 rotatable in the direction of arrow 121.

The winding apparatus includes drum 119 having a gear 123 that is rotated by an elongated gear 125 mounted on a shaft 127. A left-hand helical gear 129 is also mounted on shaft 127 and is caused to rotate when shaft 127 moves around a fixed left-hand helical gear 131 supported in fixed position by stationary shaft 133 that extends upwardly from fixed plate 135.

Shaft 127 is caused to move around fixed gear 131 by the rotation of gear 137 on which is mounted end plates 139, 141. Shaft 127 is mounted supported at its ends in plates 139, 141. A third end plate 143 connects one end of plane 139 to an end of plate 141 to form a strong threesided box structure of plates 139, 141 and 143.

Gear 137 is caused to rotate by a pinion 145 mounted on the shaft of motor 147.

Drum shaft 149 is mounted between end plates 139 and 141 and is positioned interiorly of drum 119. A gear 151 is mounted on the end of shaft 149 and is driven by a pinion 153 of shaft 127. Pinion 153 has a slightly larger pitch diameter than elongated gear or pinion 125. Shaft 149 is provided with a cam groove 155, and drum 119 is provided with a hole 157 in which is positioned a spring-loaded stem 159 having a shoe 161 that rides in groove 155 to give axial movement to drum 119. The teeth of pinion 153 have a slightly larger pitch diameter than the teeth of pinion 125 so that the speed of the axial movement of drum 119 is slightly different than that dictated by revolutions of pinion 125 and gear 123 alone. Accordingly, courses of a succeeding layer of roving lie between courses of the next preceding layer having courses running in the same direction.

A support plate 163 is provided for supporting a bearing 165, and a bearing 167 is mounted in gear 137. Bearings 165 and 167 serve as bearings about which the entire frame assembly including gear 137 and end plates 139, 141 and 143 rotate. A bearing 169 supports gear 131, and a bearing 171 and support sleeve 173 support helical gear 129.

To raise and lower substrate 29a, a gear rack 175 is provided having a reduced end portion 177 which is received by a hole in the bottom of substrate 29a. Gear rack 175 is driven by a driving gear 179 mounted on shaft 181 of motor 183 having an electrically operated clutch on its shaft 181. When rack gear 175 is moved downwardly to deposit substrate 29a in pocket 117, switch 185 is activated to open the clutch on motor 183 thereby allowing rack gear 175 to drop quickly by gravity to a position clear of drum 119 as shown in FIG. 4. This use of the clutch-motor is advantageous over using a complicated and expensive two speed motor.

FIG. 7 is an exploded view in schematic form of the feed structure of the invention located between nucleating zone 29a and chilled base plate 16a. A ring 187, preferably of alumina, forms a funnel guide for whiskers 31 to aid in restricting the movement of the whiskers outside nucleating zone 29a. A pair of forks 189, shown separated, are brought together by a solenoid acting upon a signal from switch 185. The forks 189 hold the whiskers 31 as they pass through the forks and prevent the growth ends from turning as the roving is twisted below. A pair of split guides 191 are also brought together by a solenoid upon a signal from switch 185 and in closed position, the guides 191 form a circular or cylindrical hole through which whiskers 31 pass and are supported in an upright position. Guides 191 support the weight of the long roving and add some tension to the roving as it winds onto the drum 119.

A pair of tension rolls 193 are positioned beneath guides 191 and are spring loaded by spring 195. Rolls 193 are brought together by a solenoid that is actuated by switch 185 and they apply tension to the roving to aid in the winding of the roving onto drum 119. Rolls 193 and guides 191 are preferably made of alumina, and forks 189 are preferably made of 310 stainless steel.

Drum 119 is provided with a self-supporting cone 197 which is shown in section in FIG. 4 and which slips on and off drum 119 to form the core of the round roving. To mount cone 197 on drum 119, the operator pulls out shaft 149 from its bearings in end plates 139 and 141, and then cone 197 is slipped over drum 119. To remove cone 197 from drum 119 when the cone has been wound with whiskers, the reverse procedure is followed: shaft 149 is pulled out of its bearings and the cone 197 is pulled off drum 119.

In operation of the winding apparatus shown in FIGS. 3 to 7, substrate 31 is moved upwardly into nucleating zone 72a by rack gear 175 and nucleation is started. As nucleation progresses and the whiskers 31 grow, substrate 29a is moved downwardly by rack gear 175 at such a speed that the wisps of the whiskers 31, the growing ends, remain in nucleating zone 72a. When the sub strate 29a seats in pocket 117 of drum 119, switch 185 actuates the clutch mechanism of motor 183 to release its clutch mechanism so that rack gear 175 drops very quickly by gravity through the hole in drum 119 to the position shown free of the drum in FIG. 4. Then motor 147 starts to rotate pinion which rotates the entire assembly mounted on gear 137 including end plates 139, 141 and shafts 127 and 149. The rotation of shaft 127 in a horizontal plane parallel to the plane of gear 137 causes rotation of shaft 127 as helical gear 129 moves around fixed helical gear 131. Rotation of shaft 127 causes rotation of pinion 125 which rotates gear 123 and drum 119'. Rotation of shaft 127 also causes rotation of pinion 147 which rotates gear 151 and drum shaft 149 at a different rate of speed from the rotation of gear 123 and drum 119.

With drum 119 rotating, the whisker roving is wound on drum 119 as the action of shoe 161 in groove moves drum 119 back and forth longitudinally. Because pinion 153 rotates gear 151 at a diiferent speed than that which pinion 155 rotates gear 123, the courses of a succeeding layer of roving lie between the courses of the next preceding layer having courses running in the same direction.

The feed of the roving into the drum is controlled by ring 187, forks 189, guides 191 and tension rolls 193 positioned above the drum.

When the roving has been fully wound on drum 119, the winding is removed by removing cone 197 from the drum in the manner herein before described. Then the cone is removed from the interior of the coil, and the strand of whiskers may be unwound from the coil by pulling from the inside or interior of the coil.

The entire apparatus may be used vertically inverted, and the resetting of the mechanism is simplified by using motors with clutches in their output shafts. The twist in the roving is preferably in the order of one twist per three inch length of roving, and the pull rate of the roving is preferably about four inch per hour or faster.

What is claimed is:

1. An oven for making whiskers from a vapor comprising a housing containing a chilled base plate, a first and second support post extending upwardly from the base plate, an upper and lower support plate mounted on the posts, a hollow heating element mounted between the support plates, and a stage within the heating element defining a crystallization chamber and supporting a substrate on which whiskers are grown, and means feeding the vapor form of whisker continuously into the crystallization chamber.

2. The oven of claim 1, including an integral hollow cylinder of fused quartz positioned between the support plates and around the heating element for preventing excessive heat loss outwardly.

3. The oven of claim 1 wherein means is provided for raising and lowering said substrate.

4. The oven of claim 1, said means for feeding said vapor into the oven toward said substrate including a stainless steel sleeve threaded into the base plate, a vapor tube extending through the sleeve, and a plastic insert positioned between the tube and the sleeve to electrically insulate the tube from the base plate.

5. The oven of claim 1, wherein the substrate is covered with rhodium.

6. The oven of claim 1, wherein the substrate is made of a material selected from the group consisting of rhodium, 300 series stainless steel, beryllium oxide, alumina, copper, cobalt, and nickel.

7. The oven of claim 1, including means for supplying vapor to the oven so that it flows into a whisker deposition zone and forms a turbulence with vapor convection currents created by the coolness of said chilled base plate.

8. The oven of claim 7 including a second means for moving said drum axially during its rotation so that courses of a succeeding layer of roving lie between courses of the next preceding layer having courses running in the same direction.

9. The oven of claim 8 wherein the drum includes a pocket that receives the substrate.

10. The oven of claim 9 wherein said means for moving said substrate into said drum includes a rack gear which passes through a hole in the drum and through said pocket and is provided with an end that supports the substrate.

11. The oven of claim 10 including a motor having a clutch connected to the rack gear for raising the substrate to the nucleating zone and for lowering the substrate into the drum pocket and for dropping the rack gear clear of the drum quickly by gravity by releasing the clutch.

12. An oven for making whiskers from a vapor comprising a housing, a nucleating zone within the housing, a substrate on which whiskers are grown positioned in said nucleating zone, means for forming the whiskers into a roving, a rotatable drum, means for moving said substrate into said drum and leaving the whisker ends in said nucleating zone, and means for rotating said drum to wind the whiskers on the drum in a roving.

13. The oven of claim 12 including means for moving said drum axially during its rotation, said means including a shaft positioned interiorly of the drum, a driven gear mounted on said shaft, a cam groove formed in said shaft, and cam follower means extending from the drum to the grooves for moving the drum back and forth axially as the cam follower means travels along said grooves.

References Cited UNITED STATES PATENTS 2,753,280 7/1956 Moore 23273 2,890,139 6/1959 Shockley 23273 3,057,703 10/1962 Knapic 23273 3,186,880 6/1965 Skaggs 23294 3,228,756 1/1966 Hergenrother 23-301 3,477,959 11/1969 Colton 23273 3,519,394 7/1970 Petit-Le Du 23-273 3,536,519 10/1970 Glass 23301 3,565,703 2/1971 Kamath 23301 3,615,258 10/1971 Glass 23294 FOREIGN PATENTS 1,176,625 8/1964 Germany 23301 NORMAN YUDKOFF, Primary Examiner R. T. FOSTER, Assistant Examiner US. Cl. X.R. 23--301 SP. 294 

